You can’t say you have all the answers if you haven’t asked all the questions. So, at a conference on the medical and ecological consequences of the Fukushima nuclear disaster, held to commemorate the second anniversary of the earthquake and tsunami that struck northern Japan, there were lots of questions. Questions about what actually happened at Fukushima Daiichi in the first days after the quake, and how that differed from the official report; questions about what radionuclides were in the fallout and runoff, at what concentrations, and how far they have spread; and questions about what near- and long-term effects this disaster will have on people and the planet, and how we will measure and recognize those effects.

A distinguished list of epidemiologists, oncologists, nuclear engineers, former government officials, Fukushima survivors, anti-nuclear activists and public health advocates gathered at the invitation of The Helen Caldicott Foundation and Physicians for Social Responsibility to, if not answer all these question, at least make sure they got asked. Over two long days, it was clear there is much still to be learned, but it was equally clear that we already know that the downsides of nuclear power are real, and what’s more, the risks are unnecessary. Relying on this dirty, dangerous and expensive technology is not mandatory–it’s a choice. And when cleaner, safer, and more affordable options are available, the one answer we already have is that nuclear is a choice we should stop making and a risk we should stop taking.

“No one died from the accident at Fukushima.” This refrain, as familiar as multiplication tables and sounding about as rote when recited by acolytes of atomic power, is a close mirror to versions used to downplay earlier nuclear disasters, like Chernobyl and Three Mile Island (as well as many less infamous events), and is somehow meant to be the discussion-ender, the very bottom-line of the bottom-line analysis that is used to grade global energy options. “No one died” equals “safe” or, at least, “safer.” Q.E.D.

But beyond the intentional blurring of the differences between an “accident” and the probable results of technical constraints and willful negligence, the argument (if this saw can be called such) cynically exploits the space between solid science and the simple sound bite.

“Do not confuse narrowly constructed research hypotheses with discussions of policy,” warned Steve Wing, Associate Professor of Epidemiology at the University of North Carolina’s Gillings School of Public Health. Good research is an exploration of good data, but, Wing contrasted, “Energy generation is a public decision made by politicians.”

Surprisingly unsurprising

A public decision, but not necessarily one made in the public interest. Energy policy could be informed by health and environmental studies, such as the ones discussed at the Fukushima symposium, but it is more likely the research is spun or ignored once policy is actually drafted by the politicians who, as Wing noted, often sport ties to the nuclear industry.

The link between politicians and the nuclear industry they are supposed to regulate came into clear focus in the wake of the March 11, 2011 Tohoku earthquake and tsunami–in Japan and the United States.

The boiling water reactors (BWRs) that failed so catastrophically at Fukushima Daiichi were designed and sold by General Electric in the 1960s; the general contractor on the project was Ebasco, a US engineering company that, back then, was still tied to GE. General Electric had bet heavily on nuclear and worked hand-in-hand with the US Atomic Energy Commission (AEC–the precursor to the NRC, the Nuclear Regulatory Commission) to promote civilian nuclear plants at home and abroad. According to nuclear engineer Arnie Gundersen, GE told US regulators in 1965 that without quick approval of multiple BWR projects, the giant energy conglomerate would go out of business.

It was under the guidance of GE and Ebasco that the rocky bluffs where Daiichi would be built were actually trimmed by 10 meters to bring the power plant closer to the sea, the water source for the reactors’ cooling systems–but it was under Japanese government supervision that serious and repeated warnings about the environmental and technological threats to Fukushima were ignored for another generation.

Failures at Daiichi were completely predictable, observed David Lochbaum, the director of the Nuclear Safety Project at the Union of Concerned Scientists, and numerous upgrades were recommended over the years by scientists and engineers. “The only surprising thing about Fukushima,” said Lochbaum, “is that no steps were taken.”

The surprise, it seems, should cross the Pacific. Twenty-two US plants mirror the design of Fukushima Daiichi, and many stand where they could be subject to earthquakes or tsunamis. Even without those seismic events, some US plants are still at risk of Fukushima-like catastrophic flooding. Prior to the start of the current Japanese crisis, the Nuclear Regulatory Commission learned that the Oconee Nuclear Plant in Seneca, South Carolina, was at risk of a major flood from a dam failure upstream. In the event of a dam breach–an event the NRC deems more likely than the odds that were given for the 2011 tsunami–the flood at Oconee would trigger failures at all four reactors. Beyond hiding its own report, the NRC has taken no action–not before Fukushima, not since.

The missing link

But it was the health consequences of nuclear power–both from high-profile disasters, as well as what is considered normal operation–that dominated the two days of presentations at the New York Academy of Medicine. Here, too, researchers and scientists attempted to pose questions that governments, the nuclear industry and its captured regulators prefer to ignore, or, perhaps more to the point, omit.

Dr. Hisako Sakiyama, a member of the Fukushima Nuclear Accident Independent Investigation Commission, has been studying the effects of low-dose radiation. Like others at the symposium, Dr. Sakiyama documented the linear, no-threshold risk model drawn from data across many nuclear incidents. In essence, there is no point at which it can be said, “Below this amount of radiation exposure, there is no risk.” And the greater the exposure, the greater the risk of health problems, be they cancers or non-cancer diseases.

Dr. Sakiyama contrasted this with the radiation exposure limits set by governments. Japan famously increased what it called acceptable exposure quite soon after the start of the Fukushima crisis, and, as global background radiation levels increase as a result of the disaster, it is feared this will ratchet up what is considered “safe” in the United States, as the US tends to discuss limits in terms of exposure beyond annual average background radiation. Both approaches lack credibility and expose an ugly truth. “Debate on low-dose radiation risk is not scientific,” explained Sakiyama, “but political.”

And the politics are posing health and security risks in Japan and the US.

Akio Matsumura, who spoke at the Fukushima conference in his role as founder of the Global Forum of Spiritual and Parliamentary Leaders for Human Survival, described a situation at the crippled Japanese nuclear plant that is much more perilous, even today, than leaders are willing to acknowledge. Beyond the precarious state of the spent fuel pool above reactor four, Matsumura also cited the continued melt-throughs of reactor cores (which could lead to a steam explosion), the high levels of radiation at reactors one and three (making any repairs impossible), and the unprotected pipes retrofitted to help cool reactors and spent fuel. “Probability of another disaster,” Matsumura warned, “is higher than you think.”

Matsumura lamented that investigations of both the technical failures and the health effects of the disaster are not well organized. “There is no longer a link between scientists and politicians,” said Matsumura, adding, “This link is essential.”

The Union of Concerned Scientists’ Lochbaum took it further. “We are losing the no-brainers with the NRC,” he said, implying that what should be accepted as basic regulatory responsibility is now subject to political debate. With government agencies staffed by industry insiders, “the deck is stacked against citizens.”

Both Lochbaum and Arnie Gundersen criticized the nuclear industry’s lack of compliance, even with pre-Fukushima safety requirements. And the industry’s resistance undermines nuclear’s claims of being competitive on price. “If you made nuclear power plants meet existing law,” said Gundersen, “they would have to shut because of cost.”

But without stronger safety rules and stricter enforcement, the cost is borne by people instead.

Determinate data, indeterminate risk

While the two-day symposium was filled with detailed discussions of chemical and epidemiologic data collected throughout the nuclear age–from Hiroshima through Fukushima–a cry for more and better information was a recurring theme. In a sort of wily corollary to “garbage in, garbage out,” experts bemoaned what seem like deliberate holes in the research.

Even the long-term tracking study of those exposed to the radiation and fallout in Japan after the atomic blasts at Hiroshima and Nagasaki–considered by many the gold-standard in radiation exposure research because of the large sample size and the long period of time over which data was collected–raises as many questions as it answers.

The Hiroshima-Nagasaki data was referenced heavily by Dr. David Brenner of the Center for Radiological Research, Columbia University College of Physicians and Surgeons. Dr. Brenner praised the study while using it to buttress his opinion that, while harm from any nuclear event is unfortunate, the Fukushima crisis will result in relatively few excess cancer deaths–something like 500 in Japan, and an extra 2,000 worldwide.

“There is an imbalance of individual risk versus overall anxiety,” said Brenner.

But Dr. Wing, the epidemiologist from the UNC School of Public Health, questioned the reliance on the atom bomb research, and the relatively rosy conclusions those like Dr. Brenner draw from it.

“The Hiroshima and Nagasaki study didn’t begin till five years after the bombs were dropped,” cautioned Wing. “Many people died before research even started.” The examination of cancer incidence in the survey, Wing continued, didn’t begin until 1958–it misses the first 13 years of data. Research on “Black Rain” survivors (those who lived through the heavy fallout after the Hiroshima and Nagasaki bombings) excludes important populations from the exposed group, despite those populations’ high excess mortality, thus driving down reported cancer rates for those counted.

The paucity of data is even more striking in the aftermath of the Three Mile Island accident, and examinations of populations around American nuclear power plants that haven’t experienced high-profile emergencies are even scarcer. “Studies like those done in Europe have never been done in the US,” said Wing with noticeable regret. Wing observed that a German study has shown increased incidences of childhood leukemia near operating nuclear plants.

There is relatively more data on populations exposed to radioactive contamination in the wake of the Chernobyl nuclear accident. Yet, even in this catastrophic case, the fact that the data has been collected and studied owes much to the persistence of Alexey Yablokov of the Russian Academy of Sciences. Yablokov has been examining Chernobyl outcomes since the early days of the crisis. His landmark collection of medical records and the scientific literature, Chernobyl: Consequences of the Catastrophe for People and the Environment, has its critics, who fault its strong warnings about the long-term dangers of radiation exposure, but it is that strident tone that Yablokov himself said was crucial to the evolution of global thinking about nuclear accidents.

Because of pressure from the scientific community and, as Yablokov stressed at the New York conference, pressure from the general public, as well, reaction to accidents since Chernobyl has evolved from “no immediate risk,” to small numbers who are endangered, to what is now called “indeterminate risk.”

Calling risk “indeterminate,” believe it or not, actually represents a victory for science, because it means more questions are asked–and asking more questions can lead to more and better answers.

Yablokov made it clear that it is difficult to estimate the real individual radiation dose–too much data is not collected early in a disaster, fallout patterns are patchy and different groups are exposed to different combinations of particles–but he drew strength from the volumes and variety of data he’s examined.

Indeed, as fellow conference participant, radiation biologist Ian Fairlie, observed, people can criticize Yablokov’s advocacy, but the data is the data, and in the Chernobyl book, there is lots of data.

Complex and consequential

Data presented at the Fukushima symposium also included much on what might have been–and continues to be–released by the failing nuclear plant in Japan, and how that contamination is already affecting populations on both sides of the Pacific.

Several of those present emphasized the need to better track releases of noble gasses, such as xenon-133, from the earliest days of a nuclear accident–both because of the dangers these elements pose to the public and because gas releases can provide clues to what is unfolding inside a damaged reactor. But more is known about the high levels of radioactive iodine and cesium contamination that have resulted from the Fukushima crisis.

In the US, since the beginning of the disaster, five west coast states have measured elevated levels of iodine-131 in air, water and kelp samples, with the highest airborne concentrations detected from mid-March through the end of April 2011. Iodine concentrates in the thyroid, and, as noted by Joseph Mangano, director of the Radiation and Public Health Project, fetal thyroids are especially sensitive. In the 15 weeks after fallout from Fukushima crossed the Pacific, the western states reported a 28-percent increase in newborn (congenital) hypothyroidism (underactive thyroid), according to the Open Journal of Pediatrics. Mangano contrasted this with a three-percent drop in the rest of the country during the same period.

The most recent data from Fukushima prefecture shows over 44 percent of children examined there have thyroid abnormalities.

Of course, I-131 has a relatively short half-life; radioactive isotopes of cesium will have to be tracked much longer.

With four reactors and densely packed spent fuel pools involved, Fukushima Daiichi’s “inventory” (as it is called) of cesium-137 dwarfed Chernobyl’s at the time of its catastrophe. Consequently, and contrary to some of the spin out there, the Cs-137 emanating from the Fukushima plant is also out-pacing what happened in Ukraine.

Estimates put the release of Cs-137 in the first months of the Fukushima crisis at between 64 and 114 petabecquerels (this number includes the first week of aerosol release and the first four months of ocean contamination). And the damaged Daiichi reactors continue to add an additional 240 million becquerels of radioactive cesium to the environment every single day. Chernobyl’s cesium-137 release is pegged at about 84 petabecquerels. (One petabecquerel equals 1,000,000,000,000,000 becquerels.) By way of comparison, the nuclear “device” dropped on Hiroshima released 89 terabecquerels (1,000 terabecquerels equal one petabecquerel) of Cs-137, or, to put it another way, Fukushima has already released more than 6,400 times as much radioactive cesium as the Hiroshima bomb.

The effects of elevated levels of radioactive cesium are documented in several studies across post-Chernobyl Europe, but while the implications for public health are significant, they are also hard to contain in a sound bite. As medical genetics expert Wladimir Wertelecki explained during the conference, a number of cancers and other serious diseases emerged over the first decade after Chernobyl, but the cycles of farming, consuming, burning and then fertilizing with contaminated organic matter will produce illness and genetic abnormalities for many decades to come. Epidemiological studies are only descriptive, Wertelecki noted, but they can serve as a “foundation for cause and effect.” The issues ahead for all of those hoping to understand the Fukushima disaster and the repercussions of the continued use of nuclear power are, as Wertelecki pointed out, “Where you study and what you ask.”

One of the places that will need some of the most intensive study is the Pacific Ocean. Because Japan is an island, most of Fukushima’s fallout plume drifted out to sea. Perhaps more critically, millions of gallons of water have been pumped into and over the damaged reactors and spent fuel pools at Daiichi, and because of still-unplugged leaks, some of that water flows into the ocean every day. (And even if those leaks are plugged and the nuclear fuel is stabilized someday, mountain runoff from the area will continue to discharge radionuclides into the water.) Fukushima’s fisheries are closed and will remain so as far into the future as anyone can anticipate. Bottom feeders and freshwater fish exhibit the worst levels of cesium, but they are only part of the picture. Ken Beusseler, a marine scientist at Woods Hole Oceanographic Institute, described a complex ecosystem of ocean currents, food chains and migratory fish, some of which carry contamination with them, some of which actually work cesium out of their flesh over time. The seabed and some beaches will see increases in radio-contamination. “You can’t keep just measuring fish,” warned Beusseler, implying that the entire Pacific Rim has involuntarily joined a multidimensional long-term radiation study.

For what it’s worth

Did anyone die as a result of the nuclear disaster that started at Fukushima Daiichi two years ago? Dr. Sakiyama, the Japanese investigator, told those assembled at the New York symposium that 60 patients died while being moved from hospitals inside the radiation evacuation zone–does that count? Joseph Mangano has reported on increases in infant deaths in the US following the arrival of Fukushima fallout–does that count? Will cancer deaths or future genetic abnormalities, be they at the low or high end of the estimates, count against this crisis?

It is hard to judge these answers when the question is so very flawed.

As discussed by many of the participants throughout the Fukushima conference, a country’s energy decisions are rooted in politics. Nuclear advocates would have you believe that their favorite fuel should be evaluated inside an extremely limited universe, that there is some level of nuclear-influenced harm that can be deemed “acceptable,” that questions stem from the necessity of atomic energy instead of from whether civilian nuclear power is necessary at all.

The nuclear industry would have you do a cost-benefit analysis, but they’d get to choose which costs and benefits you analyze.

While all this time has been and will continue to be spent on tracking the health and environmental effects of nuclear power, it isn’t a fraction of a fraction of the time that the world will be saddled with fission’s dangerous high-level radioactive trash (a problem without a real temporary storage program, forget a permanent disposal solution). And for all the money that has been and will continue to be spent compiling the health and environmental data, it is a mere pittance when compared with the government subsidies, liability waivers and loan guarantees lavished upon the owners and operators of nuclear plants.

Many individual details will continue to emerge, but a basic fact is already clear: nuclear power is not the world’s only energy option. Nor are the choices limited to just fossil and fissile fuels. Nuclear lobbyists would love to frame the debate–as would advocates for natural gas, oil or coal–as cold calculations made with old math. But that is not where the debate really resides.

If nuclear reactors were the only way to generate electricity, would 500 excess cancer deaths be acceptable? How about 5,000? How about 50,000? If nuclear’s projected mortality rate comes in under coal’s, does that make the deaths–or the high energy bills, for that matter–more palatable?

As the onetime head of the Tennessee Valley Authority, David Freeman, pointed out toward the end of the symposium, every investment in a new nuclear, gas or coal plant is a fresh 40-, 50-, or 60-year commitment to a dirty, dangerous and outdated technology. Every favor the government grants to nuclear power triggers an intense lobbying effort on behalf of coal or gas, asking for equal treatment. Money spent bailing out the past could be spent building a safer and more sustainable future.

Nuclear does not exist in a vacuum; so neither do its effects. There is much more to be learned about the medical and ecological consequences of the Fukushima nuclear disaster–but that knowledge should be used to minimize and mitigate the harm. These studies do not ask and are not meant to answer, “Is nuclear worth it?” When the world already has multiple alternatives–not just in renewable technologies, but also in conservation strategies and improvements in energy efficiency–the answer is already “No.”

A version of this story previously appeared onTruthout; no version may be reprinted without permission.

An Alert is the second rung on the NRC’s four-point emergency classification scale. It indicates “events are in process or have occurred which involve an actual or potential substantial degradation in the level of safety of the plant.” (By way of reference, the fourth level–a General Emergency–indicates substantial core damage and a potential loss of containment.)

As reported earlier, Oyster Creek’s coolant intake structure was surrounded by floodwaters that arrived with Sandy. Oyster Creek’s 47-year-old design requires massive amounts of external water that must be actively pumped through the plant to keep it cool. Even when the reactor is offline, as was the case on Monday, water must circulate through the spent fuel pools to keep them from overheating, risking fire and airborne radioactive contamination.

The water level was more than six feet above normal. At seven feet, the plant would lose the ability to cool its spent fuel pool in the normal fashion, according to Neil Sheehan, a spokesman for the Nuclear Regulatory Commission.

The plant would probably have to switch to using fire hoses to pump in extra water to make up for evaporation, Mr. Sheehan said, because it could no longer pull water out of Barnegat Bay and circulate it through a heat exchanger, to cool the water in the pool.

If hoses desperately pouring water on endangered spent fuel pools remind you of Fukushima, it should. Oyster Creek is the same model of GE boiling water reactor that failed so catastrophically in Japan.

The NRC press release (PDF) made a point–echoed in most traditional media reports–of noting that Oyster Creek’s reactor was shut down, as if to indicate that this made the situation less urgent. While not having to scram a hot reactor is usually a plus, this fact does little to lessen the potential problem here. As nuclear engineer Arnie Gundersen told Democracy Now! before the Alert was declared:

[Oyster Creek is] in a refueling outage. That means that all the nuclear fuel is not in the nuclear reactor, but it’s over in the spent fuel pool. And in that condition, there’s no backup power for the spent fuel pools. So, if Oyster Creek were to lose its offsite power—and, frankly, that’s really likely—there would be no way cool that nuclear fuel that’s in the fuel pool until they get the power reestablished. Nuclear fuel pools don’t have to be cooled by diesels per the old Nuclear Regulatory Commission regulations.

A site blackout (SBO) or a loss of coolant issue at Oyster Creek puts all of the nuclear fuel and high-level radioactive waste at risk. The plant being offline does not change that, though it does, in this case, increase the risk of an SBO.

But in the statement from the NRC, there was also another point they wanted to underscore (or one could even say “brag on”): “As of 9 p.m. EDT Monday, no plants had to shut down as a result of the storm.”

The shutdown was caused by an electrical grid disturbance that caused the unit’s output breakers to open. When the unit’s electrical output breakers open, there is nowhere to “push” or transmit the power and the unit is appropriately designed to shut down under these conditions.

“Our preliminary investigation identified a lighting pole in the Scriba switchyard that had fallen onto an electrical component. This is believed to have caused the grid disturbance. We continue to evaluate conditions in the switchyard,” said Jill Lyon, company spokesperson.

Nine Mile Point Nuclear Station consists of two GE boiling water reactors, one of which would be the oldest operating in the US were it not for Oyster Creek. They are located just outside Oswego, NY, on the shores of Lake Ontario. Just one week ago, Unit 1–the older reactor–declared an “unusual event” as the result of a fire in an electrical panel. Then, on Monday, the reactor scrammed because of a grid disturbance, likely caused by a lighting pole knocked over by Sandy’s high winds.

An hour and forty-five minutes later, and 250 miles southeast, another of the nation’s ancient reactors also scrammed because of an interruption in offsite power. Indian Point, the very old and very contentious nuclear facility less than an hour’s drive north of New York City, shut down because of “external grid issues.” And Superstorm Sandy has given Metropolitan New York’s grid a lot of issues.

While neither of these shutdowns is considered catastrophic, they are not as trivial as the plant operators and federal regulators would have you believe. First, emergency shutdowns–scrams–are not stress-free events, even for the most robust of reactors. As discussed here before, it is akin to slamming the breaks on a speeding locomotive. These scrams cause wear and tear aging reactors can ill afford.

Second, scrams produce pressure that usually leads to the venting of some radioactive vapor. Operators and the NRC will tell you that these releases are well within “permissible” levels–what they can’t tell you is that “permissible” is the same as “safe.”

Operators and the Nuclear Regulatory Commission spokes-folks like to remind all who will listen (or, at least, all who will transcribe) that nuclear reactors are the proverbial house of bricks–a hurricane might huff and puff, but the reinforced concrete that makes up a typical containment building will not blow in. But that’s not the issue, and the NRC, at least, should know it.

Loss of power (SBOs) and loss of coolant accidents (LOCAs) are what nuclear watchdogs were warning about in advance of Sandy, and they are exactly the problems that presented themselves in New York and New Jersey when the storm hit.

The engineers of the Titanic claimed that they had built the unsinkable ship, but human error, corners cut on construction, and a big chunk of ice cast such hubris asunder. Nuclear engineers, regulators and operators love to talk of four-inch thick walls and “defense-in-depth” backup systems, but the planet is literally littered with the fallout of their folly. Nuclear power systems are too complex and too dangerous for the best of times and the best laid plans. How are they supposed to survive the worst of times and no plans at all?

The Crystal River story is long and sordid. The containment building cracked first during its construction in 1976. That crack was in the dome, and was linked to a lack of steel reinforcement. Most nuclear plants use four layers of steel reinforcement; Crystal River used only one. The walls were built as shoddily as the dome.

The latest problems started when Crystal River needed to replace the steam generator inside the containment building. Rather than use an engineering firm like Bechtel or SGT–the companies that had done the previous 34 such replacements in the US–Progress decided it would save a few bucks and do the job itself.

Over the objections of on-site workers, Progress used a different method than the industry standard to cut into the containment building. . . and that’s when this new cracking began. It appears that every attempt since to repair the cracks has only led to new “delamination” (as the industry calls it).

The Crystal River reactor has been plagued with problems ever since PEF self-managed a steam generation replacement project in September 2009. The replacement project was intended to last 3 months, until PEF informed the Commission that it had cracked the containment structure during the detensioning phase of the project. PEF subsequently announced that the CR3 reactor would be repaired and back in service by the 3rd quarter of 2010…then by the 4th quarter of 2010…and then by the first quarter of 2011. On March 15, 2011 PEF informed the Commission that it had cracked the reactor again during the retensioning process and subsequently told the Commission that it estimated repair costs of $1.3 billion and a return to service in 2014. Shortly thereafter, the Humpty Dumpty Crystal River reactor suffered yet another crack on July 26, 2011.

That July crack was later revealed to be 12-feet long and 4-feet wide–and here, at least when it came to notifying the Nuclear Regulatory Commission, “later” means much later. . . like four months later.

The issue, of course–as anyone with a lifetime crack habit will tell you–is that this all gets very expensive. Not only is there the cost of the repairs. . . and the repairs to the repairs. . . and the repairs to the repairs to the repairs. . . there is the cost of replacing the energy that was supposed to be supplied to PEF customers by the crippled reactor.

And then there is the cost of the new reactors. . . .

Wait, what?

Yes, based on the amazing success they have had managing Crystal River–and something called a “determination of need,” which was granted in 2008–Progress Energy holds out hope of someday building two of those trendy new AP1000 nuclear reactors at another Florida site, this one in Levy County.

And who is expected to pick up the tab? Who is on the hook, not just for repairs and replacement energy at Crystal River, but for PEF keeping its options open at Levy? Well, not surprisingly in “privatize profits, socialize risk” America, the plan was to stick Florida ratepayers with the bill (again Footprints provides the numbers):

Customer bills for instance, were expected to increase by $16/mo. in 2016; $26/mo. in 2017 and a whopping $49/mo. in 2020. Initially, Progress expected the proposed reactors to cost $4-6 billion each, coming online beginning in 2016. Just a few years later, the estimated costs have skyrocketed to over $22 billion and the online date, if the reactors ever even come online, has bumped back to 2021 and 2022. And the Office of Public Counsel believes that PEF may not intend to complete the reactors until 2027, if at all. The company has spent over $1 billion dollars on the Levy nuclear reactors and has yet to commit to build them. And the company is entitled to recover all its preconstruction and carrying costs from its customers before even a kilowatt of electricity is produced. In fact, even if the project is never completed PEF can recover all its construction costs from customers courtesy of the 2006 anti-consumer “early cost recovery” state law…essentially a nuclear tax scheme.

The state Public Service Commission on Wednesday unanimously approved an agreement that will increase the power bills of Progress Energy Florida customers — who already pay among the highest rates in the state.

It is supposed to be a win for consumers.

The deal includes a $288 million “refund” of money customers were to pay to replace power from the crippled Crystal River nuclear plant, which has been offline since fall 2009 and might never return to service.

PSC staff concluded that customer rates still would increase. The average Progress customer’s bill on Jan. 1 is expected to increase $4.93 a month per 1,000 kilowatt hours of usage, from $123.19 to $128.12, subject to adjustments for fuel costs.

That’s a “win” for Floridians, it seems, because they are paying out something less for Progress Energy’s mistakes–at least in the near term. But even that caveat is subject to scrutiny:

While the agreement provides a replacement power cost refund over 3 years of $288 million to PEF customers (due to the CR3 outage) – it comes packaged with a base rate increase of $150 million and it precludes the parties from challenging up to $1.9 billion (yes, billion) fuel and replacement power costs from 2009 to 2016.

And that’s not all. Also in the agreement is a requirement that PEF start (yes, that is start) the latest repairs on Crystal River by the end of 2012; if they do not, Progress has to “refund” an additional $100 million to consumers. Missing, however, from the agreement is any new estimate (given the latest revelations, not to mention any post-Fukushima upgrades required) of the cost should PEF actually try to remedy all of Crystal River’s problems–and perhaps even more glaring, questions remain as to who will pay (and how much it will cost) should PEF decide to stop throwing good money after bad and decommission Crystal River reactor 3.

PEF hasn’t committed to actually building the Levy Co. reactors. Having customers pay for the company just to maintain the “option” at a later date to build reactors is unfair to today’s customers – and runs counter to the Commission’s “intent to build” standard. The agreement allows the company to collect another $350 million from customers, presumably for pursuing their Nuclear Regulatory Commission license (without any prudency review) for reactors it hasn’t committed to build? In fact, the agreement contemplates that the company will cancel its engineering and procurement contracts as well, further demonstrating the unlikelihood of project completion.

The big difference so far between Levy and Vogtle has been Southern’s ability to line up some financing for its Georgia construction–thanks to $8.33 billion in federal loan guarantees granted the project by the Obama administration almost two years in advance of the NRC approval.

Progress Energy Florida officials said Thursday that President Obama’s plan to offer federal loan guarantees to encourage investment in nuclear power plant construction will be a strong incentive to move forward with the company’s proposed Levy County plant.

The project, however, is facing delays of between 20 to 36 months due to economic and regulatory problems, making the plant’s future uncertain despite the company’s insistence the project isn’t cancelled.

“It (the loan guarantee program) will definitely play a role in that decision (whether to continue with the project). It is one of many, but a very important one,” said Progress Energy spokesman Mike Hughes.

That was in 2010, right after President Obama announced the new Department of Energy loan program–but two years later, PEF has not secured a federal guarantee, and so has not secured any financing. . . and thus has also not committed to ever building the Levy plant. But none of that has stopped Progress from collecting money from Florida consumers just to keep hope alive, as it were. And none of that has apparently stopped any of Florida’s public service commissioners from telling PEF that this practice is just jake with them.

Even with NRC approval and some federally guaranteed money, it is still not a sure bet that the Vogtle AP1000 reactors will ever come on line. PEF’s Levy project has no license and no loan guarantee.

The folks at Progress Energy are not stupid–at least not when it comes to short-term financial gain–they know how very slim their chances are of ever pushing even a single kilowatt out of Levy County, but they also know where the profit is in the nuclear power game. It is not, quite obviously, in the construction of nuclear power plants–rife as that process is with lengthy delays and massive cost overruns–and it is not, some might be surprised to learn, so much in electric generation, given that plants in the US are now suffering “unusual events” that force one or more of them offline pretty much every week. Unusual events cost money–in parts and labor, and in time lost to repairs and inspections–and, as has been demonstrated at Crystal River, there is the cost of replacement energy.

No, the real profits in the nuclear racket come from the ability to collect on services not rendered and a product not delivered, or at least not delivered regularly. Because the system backstops the financing of nuclear facilities while also allowing plant operators to pass both real and anticipated costs onto ratepayers, many American taxpayers are poised to pay twice for nuclear power plants that don’t produce power.

And it would be remiss to close without adding a few more points.

Much has been made of the failure of solar panel manufacturer Solyndra, which also received aid from the federal government in the form of loan guarantees. Solyndra ultimately got $527 million from the government; contrast that with what has been granted to Southern for Vogtle. Or, starker still, look at the entire alternative energy loan program, now projected to cost out at under $3 billion, and then look back to 2010, when Barack Obama pledged $54.5 billion to the DOE loan guarantee program designed to foster investment in nuclear power.

In addition, while the government will actually recoup most of the money lost on Solyndra when the factory and inventory are auctioned off, the “leftovers” from a failed nuclear plant–even the parts that are not contaminated with radioactivity–are much harder (if not impossible) to move.

The focus of this story has been on the costs–because the case of Progress Energy Florida is such a glaring example of how nuclear operators fleece America–but the fact that a company so focused on the bottom line, regardless of its effect on public safety, is still allowed to play with something as dangerous as a damaged nuclear power plant should not be overlooked. Alas, as was exposed last year, nuclear regulators and the nuclear industry seem to agree that safety should be addressed with an eye toward cost. So, while Crystal River is a scary mess, the reactor in question is actually offline right now. The same cannot be said, for example, about Ohio’s Davis-Besse plant, which has cracking problems of its own, but was allowed by the NRC to restart in January–over the vociferous objections of industry watchdogs, engineers, and Rep. Dennis Kucinich (D-OH).

And then there is Palisades, on the shores of Lake Michigan, where numerous events and releases of radioactivity in the last year caused the Nuclear Regulatory Commission to issue a downgrade of the plant’s safety rating–but the NRC did not order the plant to shut down. Palisades is owned by Entergy Nuclear, who was recently cited for “buying reactors cheap, then running them into the ground.” In addition to Palisades, Entergy owns nine other plants–Arkansas Nuclear One, Nebraska’s Cooper Nuclear Station, Fitzpatrick in upstate New York, Grand Gulf in Mississippi, Indian Point, just north of New York City, Pilgrim, outside of Boston, River Bend and Waterford, both in Louisiana, and Vermont Yankee.

The case of Vermont Yankee is especially upsetting. Yankee is a GE boiling water reactor, similar to the model that failed so catastrophically at Fukushima–but the NRC voted to extend its operating license just days after the Tohoku quake. The state of Vermont had a better idea, declaring that the nuclear plant should shut down by March 21, 2012. However, in January, federal district court judge J. Garvan Murtha ruled Entergy could ignore Vermont’s order and continue operating. The state is appealing the ruling, but in the meantime, Yankee continues to operate. . . and continues to leak tritium into the groundwater, and into the Connecticut River.

It is not clear who will be paying for any attempt to clean up the Vermont Yankee leak–though one can guess–nor is it clear what will happen to new nuclear waste produced after March 21, since the Vermont statehouse has forbidden any new waste storage on the site. Indeed, storing used nuclear fuel is a nationwide problem that poses real dangers in the near term, and will likely cost billions of public dollars in the long term.

And that’s the bottom line–the real bottom line–for the industry’s oft-ballyhooed “nuclear renaissance.” Plant operators and captured regulators can try to obscure the safety concerns with diversionary dustups and magical thinking, but economic realities, like facts, are stubborn. Without huge injections of public money, nuclear power simply cannot continue to function–and the public is in no mood for another multi-billion dollar government bailout.